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Wagner M , Perry RP
Characterization of the multigene family encoding the mouse S16 ribosomal protein: strategy for distinguishing an expressed gene from its processed pseudogene counterparts by an analysis of total genomic DNA
Mol Cell Biol. 1985 Dec;5(12) :3560-76
PMID: 3915781 URL: http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&dopt=Citation&list_uids=3915781
AbstractTwo genes from the family encoding mouse ribosomal protein S16 were cloned, sequenced, and analyzed. One gene was found to be a processed pseudogene, i.e., a nonfunctional gene presumably derived from an mRNA intermediate. The other S16 gene contained introns and had exonic sequences identical to those of a cloned S16 cDNA. The expression of this gene was demonstrated by Northern blot analysis of nuclear poly(A)+ RNA with cDNA and unique sequence intron probes. Each S16 intron contains a well-preserved remnant of the TACTAAC motif, which is ubiquitous in yeast introns and known to play a critical role in intron splicing. A sequence comparison with two other mouse ribosomal protein genes analyzed in our laboratory, L30 and L32, revealed common structural features which might be involved in the control and coordination of ribosomal protein gene expression. These include the lack of a canonical TATA box in the -20 to -30 region and a remarkably similar 12-nucleotide pyrimidine sequence (CTTCCYTYYTC) that spans the cap site and is flanked by C + G-rich sequences. The nature of the other members of the S16 family was evaluated by three types of experiment: a DNase I sensitivity analysis to measure the extent of chromatin condensation; an analysis of the thermal stability of cDNA-gene hybrids to estimate the extent of divergence of each gene sequence from that of the expressed gene; and a restriction fragment analysis which distinguishes intron-containing genes from intronless processed genes. The results of these analyses show that all genes except the expressed S16 gene are in a condensed chromatin configuration associated with transcriptional quiescence; that most of the genes within the S16 family have sequences greater than 7% divergent from the expressed S16 gene; and that at least 7 of the 10 S16 genes lack introns. We conclude that the ribosomal protein S16 multigene family contains one expressed intron-containing gene and nine inactive pseudogenes, most or all of which are of the processed type.
Notes0270-7306 Journal Article Review